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Research Article
Review on Advancements in the Production of Artificial Aggregates from Industrial Byproducts: A Sustainable Solution for Infrastructure Development
Noble Sahu1
Vidhi Sahu2
Manukant Dhruw3
Kamal Paikra4
Dr. Ajay Kumar Garg5
Suprabha Panda6
1,2,3,4 Department of Civil Engineering, Govt. Engineering College, Raipur, Chhattisgarh, India. 5 HOD, Department of Civil Engineering, Govt. Engineering College, Raipur, Chhattisgarh, India. 6 Assistant Professor, Department of Civil Engineering, Govt. Engineering College, Raipur, Chhattisgarh, India.
Published Online: March-April 2024
Pages: 102-105
Cite this article
↗ https://www.doi.org/10.59256/ijsreat.20240402014
References
[1]. Adhitya, B. B., Saggaff, A., Saloma, S., & Hanafiah, H. (2023). Manufacture of Geopolymer Artificial Aggregates by Pelletization and
Crushing Processes. Civil Engineering and Architecture, 11(1), 13-21.
[2]. Zhang, X., Qian, C., & Xie, D. (2022). Preparation of artificial aggregate using waste concrete powder and CO2 fixed by
microorganisms. Clean Technologies and Environmental Policy, 24(5), 1453-1467.
[3]. Yuliana, H., Karyawan, I. D. M., & Murtiadi, S. (2019). The effect of slope granulator on the characteristic of artificial geopolymer
aggregate used in pavement. Journal of Engineering Science and Technology, 14(3), 1466-1481.
[4]. Bijen, J. M. J. M. (1986). Manufacturing processes of artificial lightweight aggregates from fly ash. International Journal of Cement
Composites and Lightweight Concrete, 8(3), 191-199.
[5]. Shivaprasad, K. N., & Das, B. B. (2018). Determination of optimized geopolymerization factors on the properties of pelletized fly ash
aggregates. Construction and Building Materials, 163, 428-437.
[6]. Gunasekara, C., Setunge, S., Law, D. W., Willis, N., & Burt, T. (2018). Engineering properties of geopolymer aggregate concrete.
Journal of Materials in Civil Engineering, 30(11), 04018299.
[7]. Satpathy, H. P., Patel, S. K., & Nayak, A. N. (2019). Development of sustainable lightweight concrete using fly ash cenosphere and
sintered fly ash aggregate. Construction and Building Materials, 202, 636-655.
[8]. Slabaugh, S., Swan, C., & Malloy, R. (2007). Development and properties of Foamed synthetic Lightweight Aggregates.
[9]. Khalil, W. I., Ahmed, H. K., & Hussein, Z. M. (2015, September). Properties of artificial and sustainable lightweight aggregate. In
Proceedings of the 17th International Conference on Building Science and Engineering, Berlin, Germany (Vol. 17, No. 9, pp. 633-637)
Crushing Processes. Civil Engineering and Architecture, 11(1), 13-21.
[2]. Zhang, X., Qian, C., & Xie, D. (2022). Preparation of artificial aggregate using waste concrete powder and CO2 fixed by
microorganisms. Clean Technologies and Environmental Policy, 24(5), 1453-1467.
[3]. Yuliana, H., Karyawan, I. D. M., & Murtiadi, S. (2019). The effect of slope granulator on the characteristic of artificial geopolymer
aggregate used in pavement. Journal of Engineering Science and Technology, 14(3), 1466-1481.
[4]. Bijen, J. M. J. M. (1986). Manufacturing processes of artificial lightweight aggregates from fly ash. International Journal of Cement
Composites and Lightweight Concrete, 8(3), 191-199.
[5]. Shivaprasad, K. N., & Das, B. B. (2018). Determination of optimized geopolymerization factors on the properties of pelletized fly ash
aggregates. Construction and Building Materials, 163, 428-437.
[6]. Gunasekara, C., Setunge, S., Law, D. W., Willis, N., & Burt, T. (2018). Engineering properties of geopolymer aggregate concrete.
Journal of Materials in Civil Engineering, 30(11), 04018299.
[7]. Satpathy, H. P., Patel, S. K., & Nayak, A. N. (2019). Development of sustainable lightweight concrete using fly ash cenosphere and
sintered fly ash aggregate. Construction and Building Materials, 202, 636-655.
[8]. Slabaugh, S., Swan, C., & Malloy, R. (2007). Development and properties of Foamed synthetic Lightweight Aggregates.
[9]. Khalil, W. I., Ahmed, H. K., & Hussein, Z. M. (2015, September). Properties of artificial and sustainable lightweight aggregate. In
Proceedings of the 17th International Conference on Building Science and Engineering, Berlin, Germany (Vol. 17, No. 9, pp. 633-637)
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